Comparison of Starch Levels Reduced by High Temperature During Ripening in Japonica Rice Lines Near‐Isogenic for the Wx Locus

One problem caused by high temperature during ripening in Japonica rice cultivars is a reduction in the amount of starch in the endosperm. To better understand this deleterious effect, we compared the accumulation of the two components of starch, amylose and amylopectin in grains ripened at high (32/28 °C) and low (22/18 °C) day/night temperatures in a set of lines of Japonica cultivar Taichung 65 (T65Wx^b) that are near‐isogenic for the Wx locus, which encodes granule‐bound starch synthase I. In T65Wx^b ripened at high temperature, the amount of starch per grain decreased. However, amylose per grain significantly decreased while amylopectin per grain significantly increased. On the other hand, the amount of amylopectin in T65wx, the amylose‐free line, did not differ significantly at the high and low temperatures. These data indicated that high temperatures during ripening did not directly affect amylopectin accumulation in T65Wx^b and that the reduction in starch in T65Wx^b from the high temperatures was caused by a decrease only of amylose. The results for T65Wx^a and T65Wx^op were also consistent with this conclusion. As a result of the decrease in amylose, the outer region of starch granules from T65Wx^b ripened at the high temperatures also had less I₂KI staining. Because this fact might suggest that a portion of amylose was synthesized inside the developing granules after amylopectin synthesis in rice, the effect of amylose deposition in increasing of the density of starch granules is also discussed.     

Altered tissue-specific expression at the Wx gene of the opaque mutants in rice

Amylose content is a major determinant of the eating quality in rice. To elucidate the allelic diversity at the Waxy (Wx) gene which controls the amylose synthesis, two cultivated strains having opaque endosperms were studied. The gene responsible for opaque endosperms was introduced into the genetic background of the Japonica type of rice by successive backcrosses, and the two near-isogenic lines (NILs) were selected from the B5 generation. The genetic experiments revealed that an allele, Wx^op, controls opaque endosperms which show chalky as wx endosperms in spite of the production of amylose. Immunoblotting analysis was carried out to compare the gene expression by using the NILs with 4 different alleles (Wx^a, Wx^b, Wx^op and wx). The level of the gene product bound to starch granules was slightly lower in the NILs with Wx^op than that with Wx^b, showing a positive correlation with amylose content in the endosperm. Extracts from mature anthers indicated that the gene product was markedly reduced in the NILs with Wx^op as well as that with wx, showing an altered expression in the tissue specificity in the Wxop lines. Sequence analysis suggested that the Wx^op had been derived from Wx^a, independently of the origin of Wx^b. The importance of the gene regulation was discussed in relation to diversified phenotypes established during the domestication process.     

Genetic studies of speciation in cultivated rice. 5. Inter- and intraspecific differentiation in the waxy gene expression of rice

Summary To get an insight in the gene regulation at the waxy locus of rice, the Wx gene product (Wx protein) controlling the synthesis of amylose was examined by electrophoretic techniques. Among nonwaxy rice strains, two different alleles, Wx ^a and Wx ^b, were found at the waxy locus. Wx ^a drastically enhanced the quantitative level of Wx protein as well as the amylose content in endosperm starch as compared with Wx ^b. The alleles acted additively in triploid endosperms. This implies that regulatory elements responsible for the Wx gene expression are on the same chromosome. The distribution patterns of Wx ^a and Wx ^b in five species of Oryza revealed that the regulatory changes are closely related to racial differentiation within a common rice species (O. sativa), suggesting that Wx ^b might have been selected for through the difference in grain quality during domestication.     

Developing gene-tagged molecular markers for functional analysis of starch-synthesizing genes in rice (Oryza sativa L.)

The granule-bound starch synthase(GBSS), starch branching enzymes 1 (SBE1)and 3 (SBE3) are major enzymes involved in starch biosynthesis in rice endosperm. Available sequences of Sbe1 and Sbe3 genes encoding corresponding SBE1 and SBE3 have been used to identify homologous regions from genome databases of both the indica rice 93-11 and the japonica rice Nipponbare. Sequence diversities were exploited to develop gene-tagged markers to distinguish an indica allele from a japonica allele for both Sbe1 and Sbe3 loci. With these newly developed gene-tagged markers and available Wx gene markers, the roles of these starch-synthesizing genes (Sbe1, Sbe3, and Wx) in determining amylose content (AC) in the rice endosperm were evaluated using a double-haploid (DH)population derived from a cross between the indica rice cv. Nanjing11 and the japonica rice cv. Balilla. Only the Wx and Sbe3 loci had significant effects on the AC variation. On average, indica Wx ^a genotypes showed ∼9.1% higher AC than japonica Wx ^b genotypes, while indica Sbe3 ^a genotypes showed ∼1.0% lower AC than japonica Sbe3 ^b genotypes. A significant interaction was also observed between Wx and Sbe3 loci whereby the amylose content was 0.3% higher in Sbe3 ^a than Sbe3 ^b genotypes in the presence of the Wx ^a allele, but it was lower by 2.3% in the presence of the Wx ^b allele. Overall, polymorphisms at the Wx and Sbe3 loci together could account for 79.1% of the observed AC variation in the DH population. The use of gene-tagged markers in marker-assisted selection and gene functional analysis was also discussed. This revised version was published online in July 2006 with corrections to the Cover Date.     

Variation of <Emphasis Type="Italic">Wx</Emphasis> microsatellite allele,waxy allele distribution and differentiation of chloroplast DNA in a collection of Thai rice (<Emphasis Type="Italic">Oryza sativa</Emphasis> L.)

Eighty-two varieties of rice from different regions in Thailand were selected to explore the Waxy (Wx)gene diversity and indica-japonica differentiation of chloroplast DNA. A comparison of the 5 splice site in the first intron was made between glutinous and nonglutinous rice. It revealed that non-glutinous with low-amylose content and glutinous rice were characterized as the Wx^b allele based on the G-to-T base substitution, whereas non-glutinous rice with intermediate and high amylose carried the Wx^a allele. Four Wx microsatellite alleles, (CT)_n repeat, (n = 16,17,18 and 19) were found in glutinous rice. In contrast, non-glutinous rice showed five Wx microsatellite alleles (n = 11, 16, 17, 18 and 19). The (CT)₁₇ allele was prominent allele in Thai population, while the (CT)₁₁ allele was found only in intermediate and high amylose rice varieties from southern Thailand. Almost all of upland rice grown by various ethnic groups in northern Thailand were characterized as japonica type based on their having the PstI-12 fragment in their cpDNA, whereas most of rainfed lowland varieties from other regions of Thailand were indica. This exploration of DNA-based genetic markers is important, as it enhances our ability to describe and manipulate sources of genetic variation for rice breeding programs.     

Influence of single-nucleotide polymorphisms in the gene encoding granule-bound starch synthase I on amylose content in Vietnamese rice cultivars

Amylose content is one of the most important factors influencing the physical and chemical properties of starch in rice. Analysis of 352 Vietnamese rice cultivars revealed a wide range of variation in apparent amylose content and the expression level of granule-bound starch synthase. On the basis of single-nucleotide polymorphisms (SNP) at the splicing donor site of the first intron and in the coding region of the granule-bound starch synthase I gene, Waxy gene, alleles can be classified into seven groups that reflect differences in apparent amylose content. The very low and low apparent amylose content levels were tightly associated with a G to T in the first intron whereas intermediate and high amylose was associated with a T genotype at SNP in exon 10. The correlation between the combination of T genotype at SNP in the first intron, C in exon 6, or C in exon 10 was predominant among low amylose rice varieties. Our analysis confirmed the existence of Wx^op allele in Vietnamese rice germplasm. The results of this study suggest that the low amylose properties of Vietnamese local rice germplasm are attributable to spontaneous mutations at exons, and not at the splicing donor site.     

Isolation and characterization of a rice mutant insensitive to cool temperatures on amylose synthesis

The Wx ^b gene, one of the alleles at the rice waxy(wx) locus, is activated at cool temperatures during seed development, andas a result, a large amount of amylose is accumulated causing a reductionin rice grain quality. We found that the seeds of a du mutant couldbe visibly distinguished depending on whether they matured at cool ornormal temperatures. Using these characteristics, we isolated a mutantcandidate insensitive to cool temperatures. While the amylose content inthe original line was about 2% at a normal temperature (28 °C)and 12% at a cool temperature (21 °C), in the mutant candidate(coi) the amylose content was not affected by temperatures, i.e. theamylose content was about 3% at both temperatures. This finding incombination with the results of an immunoblot analysis indicated that theabsence of an increase in the amylose content in this mutant was caused bya constant level of Wx gene expression at normal and cooltemperature. Genetic analysis revealed that this insensitivity to cooltemperatures was caused by a single recessive mutation. This mutantshould be useful in breeding programs designed to produce rice of desiredquality at cool temperatures and in understanding genetic and molecularmechanisms that respond to slight changes in temperature.     

Amylose synthesis capacity of the three Wx genes of wheat cv. Chinese Spring

The Wx locus controls amylose synthesis in the cereal endosperm. Hexaploid wheat (Triticum aestivum L.) has the three Wx loci on chromosomes 7A ( Wx-A1), 4A (Wx-B1) and 7D (Wx-D1). To verify the effects of null alleles on reducing amylose content and determine the amylose synthesis capacity of each Wx gene independently and accurately, we produced eight possible types of recombinant lines carrying different null alleles at the Wx loci under the ‘Chinese Spring’ genetic background. Amylose content varied from 0% of the waxy ‘Chinese Spring’ to 25% of the ‘Chinese Spring’ normal type. The reducing effect of the single null alleles was the largest in Wx-B1b, and there was no significant difference between Wx-A1b and Wx-D1b. More than 3% reductions in amylose content were detected in the double null types. The results of the double null lines further demonstrated that for the capacity of amylose synthesis, Wx-B1a predominates and produces 21–22% amylose, followed by Wx-D1a (20–21%) and Wx-A1a (15–18%). These significant differences were partly correlated with variation in the amounts of the Wx proteins produced by different Wx genes. However, comparisons of the double null lines with the single null or normal lines indicated that amylose content was not linearly proportional to the number of the Wx genes, suggesting that the Wx genes act in an epistatic manner. This revised version was published online in July 2006 with corrections to the Cover Date.     

Identification of allelic variations of puroindoline genes controlling grain hardness in wheat using a modified denaturing PAGE

The amount of long chains (LC) of amylopectin in high-amylose rice is thought to be one of the important determinants of its quality when cooked. A wide range of differences in LC content have been reported in rice varieties, which can be clearly divided into four classes based on LC and apparent amylose content: namely, amylose and LC-free, low or medium-amylose and low-LC, high-amylose and medium-LC, high-amylose and high-LC. However, genetic factors controlling LC content have not been fully understood. Here, we performed quantitative trait loci (QTL) analysis of LC content using 157 recombinant inbred lines (RILs) derived from a cross of a low-LC cultivar, Hyogokitanishiki, and a high-LC line, Hokuriku 142. By analyzing randomly selected 15 RILs, it was shown that high LC content (≥11%) was associated with high setback viscosity (≥200 RVU), and that low LC (≤ 3%) was associated with low setback viscosity (≤ 130 RVU), as measured by a Rapid Visco Analyzer. With setback viscosity as an indicator for LC content, QTL analysis was conducted using 60 DNA markers including a CAPS marker that distinguished Wx a and Wx b alleles coding for granule-bound starch synthase I (GBSSI or Wx protein), the enzyme working for amylose biosynthesis. Only one QTL with a peak log of likelihood score at the wx locus was detected, and no line showing setback viscosity corresponding to the medium-LC class appeared. The fact that wx mutants of Hokuriku 142 lacked LC in their rice starch supports the view that the functional Wx allele is indispensable for LC synthesis in addition to amylose synthesis in rice endosperm. We suggest three possible reasons why no line with medium-LC content was observed. First, the locus (loci) responsible for generation of medium-LC may be located very close to the wx locus and not able to be dissected by the population and DNA markers we used. Second, there may be special QTLs for medium-LC cultivars that do not exist in low- or high-LC cultivars. Third, medium-LC cultivars may have an as-yet unidentified Wx allele with lower capability in LC synthesis compared to the Wx allele in high-LC cultivars.     

Gene dosage effect of the wheat Wx alleles and their interaction on amylose synthesis in the endosperm

To find out gene dose effect of each of the three homoeologous Wx genes and their interaction on the production of granule-bound starch synthase (GBSS I) and amylose biosynthesis in the endosperm, Chinese Spring and its near-isogenic waxy types were crossed reciprocally and, obtained a plant population with varying doses of each Wx gene. The amount of GBSSI was increased linearly with increasing gene dose of either of Wxloci. In each of the three Wx loci, the change in amylose content was linear up to 3 doses, with a more potent capacity ofWx-B1a at any dose. Higher level of amylose production was observed in the reciprocal F₁ grains than the expected effect of dose/s of each gene or additive effect of different allelic combination by artificially blend starches which have amylose produced by equivalent number ofWx alleles to that of relevant F₁ cross. When Wx-B1a and Wx-A1a were combined, increase in amylase content was not in proportion to increase in gene dosage. The enhanced amylase synthesis was shown by 2-gene and 3-geneinteraction, indicating that not only type of the three Wx genes and its dose but the interaction among them have significant roles in determining the amylose content. This revised version was published online in July 2006 with corrections to the Cover Date.     

Differences in Starch Characteristics of Rice Strains Having Different Sensitivities to Maturation Temperatures

The amylose synthesis in rice with Wx^b is affected by environmental temperature during seed development. We previously isolated a mutant candidate (coi) in which amylose synthesis is insensitive to a cool temperature. Here, the effects of maturation temperature (21 °C vs. 28 °C) on the starch characteristics of coi and its original strain 76‐3/T65 were studied. Amylose contents and gelatinization properties of 76‐3/T65 were affected by maturation temperatures, while coi was less affected. The amylopectin chain length distributions were almost the same between the two strains maturated at both temperatures. Gelatinization onset (T_o), peak (T_p), conclusion temperatures (T_c) and enthalpies (ΔH) decreased with environmental temperatures, and T_p, T_c and ΔH of coi at 21 °C were significantly higher than those of 76‐3/T65. Thus, the coi mutant, less affected by maturation temperature than that of 76‐3/T65, may be a useful strain in understanding biochemical and genetic starch biosynthesis response to slight changes in temperature.     

水稻Wx复等位基因基于PCR的功能标记开发与利用

直链淀粉含量是影响稻米食味品质的重要因素,主要由蜡质基因(Wx)调控,Wx基因座存在Wxa、Wxb、Wxin、Wxmw等多个复等位基因,通过分子标记辅助选择(marker-assisted selection,MAS)培育中低直链淀粉含量的水稻品种是提高稻米适口性的重要途径。Wx复等位基因的功能由单碱基核苷酸多态性(single nucleotide polymorphisms,SNP)决定,其检测依赖于测序或酶切,存在耗时多、费用昂贵等缺点。为提高选择效率,本文利用Wx复等位基因的SNP差异和四引物扩增受阻突变(tetra-primer ARMS-PCR)原理,进行PCR功能标记的开发。引物设计过程中,针对扩增效率低和非匹配的延伸2个技术难题,提出了调整错配位点的解决方案,成功开发了基于PCR技术的两对功能性标记Waxygt-ARMS2和Waxyac-ARMS2,可以准确区分上述复等位基因型,且具有操作简单、耗费较低的特点。利用新开发标记对辽宁省育成的部分水稻品种进行Wx基因型检测的结果表明,40份辽宁育成品种均携带Wxb基因,遗传基础单一。上述结果为利用Wx基因位点的分子标记培育中低直链淀粉含量的水稻品种,改良辽宁省水稻品种的食味品质提供了技术支撑。     

Characterization of waxy grain sorghum lines in relation to granule-bound starch synthase

The waxy phenotype, associated with endosperm containing little or no amylose, has been recognized in sorghum (Sorghum bicolor L. Moench) since 1933. Although variants of the waxy gene are well characterized in other cereals, the waxy trait has been assumed to be controlled by a single allele, wx, in sorghum. Recent improvements in technologies encourage re-examination of the waxy sorghums. The objectives of this research were therefore to identify and characterize sorghum lines with differing waxy alleles and to describe the actions of those alleles in crosses. Grain of eight waxy sorghum lines (BTxARG1, BTx630, Tx2907, B.9307, 94C274, 94C278, 94C289, 94C369), three wild-type checks (BWheatland, RTx430, BN122), and F₂ families from crosses among a subset of these lines were evaluated for presence or absence of granule-bound starch synthase (GBSS), the gene product of the wx locus, and wild-type vs. waxy endosperm. The F₂ segregation ratios were tested for fit to a 3:1 ratio using Chi-square analyses. Two distinctly different naturally occurring waxy alleles were identified: One with no GBSS (GBSS−), and one with apparently inactive GBSS present (GBSS+). We propose that the waxy allele with no GBSS be designated wx^a, and that waxy allele with apparently inactive GBSS present be designated wx^b. These two alleles are located in close proximity on the waxy locus. The wx^b allele is dominant to the wx^a allele in terms of GBSS production, and both are recessive to the wild-type Wx in terms of amylose content. The U.S. Government's right to retain a non-exclusive, royalty-free license in and to any copyright is acknowledged.     

Development of near-isogenic lines of wheat carrying different null Wx alleles and their starch properties

The granule-bound starch synthase (GBSS I) encoded by the Wxgenes, is involved in amylose synthesis. For analyses of mechanisms of amylose synthesis and associated starch properties in hexaploid wheat, eight possible genotypes having different combinations of the three null alleles at the Wx loci with a common genetic background are a prerequisite. A near-isogenic population of doubled haploid (DH) lines was produced from Chinese Spring × waxy Chinese Spring F₁ plants using the wheat × maize method. The Wx protein phenotypes of the DH progeny were examined by sodium dodecyl sulphate-polyacrylamide gel electrophoresis and found that the null alleles at each of the three Wx loci segregated in a Mendelian fashion. A field trial demonstrated no differences between the eight types for ear emergence time, plant height and grain yield traits. Amylose content in the endosperm starch was highest in the wild type while lowest in the waxy type having no Wx proteins. Comparison between single null types and double null types indicated that the amylose synthesis capacity of Wx-A1a allele is the lowest. Pasting properties of starch are the highest in the waxy type, followed by the double null types. Consequently, both peak viscosity and breakdown were negatively correlated with amylose content. The chain-length distribution analysis of amylopectin structure revealed no clear difference among the eight types,suggesting that the reduced GBSS I activity due to introgression of the null Wx alleles does not affect either the chain length or the degree of branching of amylopectin. This revised version was published online in July 2006 with corrections to the Cover Date.     

Increased regeneration from NaCl-tolerant callus in rice

Summary NaCl-tolerant calli were selected from two Japonica and two Indica rice (Oryza sativa L.) cultivars on basal media containing 6,000, 9,000, 12,000 or 15,000 ppm NaCl. Frequency of callus formation decreased with the increase of NaCl in the medium, especially in Indica. About half of the calli of Japonica cultivars selected on NaCl-ammended media survived 20,000 ppm NaCl but none of the Indica callus survived. In Japonica, more plants were regenerated from calli selected on all concentrations of NaCl media than from NaCl-free medium. Concentration of Cl^- in callus increased dramatically with increased NaCl content but peroxidase activity decreased.     

Amylose content and starch properties generated by five variant <Emphasis Type="Italic">Wx</Emphasis> alleles for granule-bound starch synthase in common wheat (<Emphasis Type="Italic">Triticum aestivum</Emphasis> L.)

In common and durum wheats (Triticum aestivum L. and T. durum Desf.), variant waxy (Wx) alleles have been reported for three Wx proteins (Wx-A1, -B1 and -D1), responsible for amylose synthesis in flour starch. Five variant alleles, Wx-A1c, -A1e, -B1c, -B1d and -D1c, were examined to elucidate their effects on amylose content in flour starch. Common wheat lines carrying a Wx protein produced by one variant (e.g., Wx-A1c) and one control (e.g., Wx-A1a) allele were bred and their starches were compared. Results showed that Wx-A1e did not produce amylose (waxy phenotype), whereas three alleles (Wx-A1c, -B1c and -B1d) reduced amylose, and -D1c might have increased it slightly. Most data on blue value, swelling power and starch paste clarity in water and dimethyl sulphoxide also suggested the variant Wx alleles either reduced or increased amylose content.     

SNPs and an insertion sequence in five Wx-A1 alleles as factors for variant Wx-A1 protein in wheat

The waxy (Wx) gene encodes a granule-bound starch synthase (also called Wx protein) that is involved in synthesizing amylose in the starch grains of cereals, including common wheat (Triticum aestivum L.). Because amylose content affects the quality of food products made from wheat flour, Wx alleles affecting amylose content are of interest. Five wheat Wx alleles (Wx-A1c, -A1d, -A1e, -A1i and -A1j) that produce polymorphic Wx proteins on electrophoretic gels were investigated in terms of amylose content in starch and DNA sequences. Measurement and electrophoresis of gelled starch showed that apparent amylose contents of the genotypes were as follows: Wx-A1e, 2.9 % (= waxy phenotype) < -A1i, 8.0 % < -A1c, 16.8 % < -A1j, 22.6 % = level of wild type allele -A1a. DNA sequencing of the five alleles identified single nucleotide polymorphisms (SNPs) and insertion/deletion variations compared to Wx-A1a. A particular SNP causing amino acid changes in Wx-A1e and -A1c was identified as the factor responsible for decreased amylose. A SNP in Wx-A1d should cause an amino acid change and be responsible for an altered Wx-A1d protein. A transposable-like element of 376 bp present in the 3′ untranslated region (UTR) of Wx-A1i most likely lowered the levels of Wx protein and amylose through aberrant mRNA. The fifth allele, Wx-A1j, possessed four SNPs, two of which altered amino acids in the Wx-A1j protein and should cause polymorphism in the Wx protein. Based on the DNA sequences, functional markers for Wx-A1c, -A1d, -A1e and -A1i were developed.     

Wide compatibility in rice (Oryza sativa L.)

Summary Wide compatible varieties (WCVs) show normal spikelet fertility in crosses with Indica and Japonica rice varieties. Crosses of Indica and Japonica varieties frequently show high spikelet sterility which prevents exploitation of heterosis for grain yield. We screened 41 rice varieties for the wide compatibility trait by crossing each with three Indica and three Japonica testers. Varieties giving fertile F₁ hybrids with both groups of testers were classified as WCVs. Seven varieties viz., BPI-76 (Indica); N 22; Lambayeque-1 and Dular (Aus); Moroberekan, Palawan and Fossa HV (Japonicas), were identified as WCVs. The frequency of WCVs was higher among Aus and Japonicas. The wide compatibility trait in varieties: Dular and Moroberekan was controlled by a single dominant gene linked with the Est-2 and Amp-3 loci (mean recombination 32.0%). Est-2 and Amp-3 showed complete linkage. Pgi-2 was found to be linked with Est-2 and Amp-3 (mean recombination 16.1%). Est-2 and Amp-3, showed a tighter linkage with C ⁺ (mean recombination 4.1%). Pgi-2 showed a lower linkage with C ⁺ (mean recombination 17.3%). The recombination values between the WC gene in Dular and C ⁺ was much higher than those reported in Japan for the WC gene (S₅ ⁿ) from Ketan Nangka. It is possible that the WC gene from Dular is different from that in Ketan Nangka. Linkage intensities with the WC gene were not strong enough to be of use for indirect selection for the wide compatibility trait. A search for a more closely linked isozyme or DNA marker was proposed.     

Indica-Japonica differentiation of paddy rice and its relationship with heterosis

The Indica‐Japonica differentiation of three photoperiod‐sensitive and/or thermosensitive genetic male‐sterile rice (PGMS or TGMS, respectively) lines and 47 male parental lines from seven ecotypes were studied for their restriction fragment length polymorphism marker data to determine which ecotype crosses with the three PGMS and/or TGMS lines could lead to higher yield potential, and to estimate the relationship between the Indica‐Japonica differentiation of parents and heterosis in grain yield and its components. The results indicated that hybrids derived from ‘N422s’ and the early‐middle ripening Indica varieties from southern China, and hybrids between ‘Pei'ai64s’ and three Japonica ecotypes, including North‐eastern Japonica varieties, restoring lines of Japonica hybrid rice and north China Japonica varieties, showed the highest grain yields. There was less variation of yield among the F1s between ‘108s’ and the seven ecotypes than among the other F₁s. Highly significant positive correlations between heterosis of the F₁ yield and genetic distance of the parents were detected, although the correlation between F₁ yield performance and genetic distance did not reach a significant level. Considerable variation of correlation between heterosis and genetic distance was also detected in the Indica × Indica crosses and Indica × Japonica crosses. There was much higher correlation (r = 0.63) between the F₁ yield performance and the genetic distance of parents in the Indica × Indica crosses than in the others. It is proposed that a genetic distance of 0.4‐0.8 between the two parents of hybrid rice might be appropriate not only for F₁ performance, but also for heterosis.     

水稻籽粒非结构性碳水化合物及充实的氮素调控

为了提高籽粒充实度和改善稻米品质,以籼、粳水稻品种为材料,研究不同氮素穗肥施用量对水稻强、弱势粒中可溶性糖积累和直链淀粉含量的影响,探讨淀粉直/支比与籽粒充实度的关系。结果表明,强、弱势粒中可溶性糖含量随着生育进程均呈“L”型变化趋势,弱势粒明显高于强势粒;不同处理间均随着氮素穗肥施用量的增加,籽粒中可溶性糖含量呈增加趋势,这说明随着施氮量的增加水稻籽粒淀粉合成能力趋于减弱。直链淀粉含量在整个籽粒灌浆期基本呈上升趋势,不同氮素处理间均随着施氮量的增加,直链淀粉含量基本上呈下降趋势,成熟期直链淀粉平均含量表现为籼稻高于粳稻。淀粉直/支比在整个籽粒灌浆期内呈上升趋势,强、弱势粒淀粉直/支比峰值出现的时间不同,表现为弱势粒滞后于强势粒。相关分析表明,强、弱势粒直/支比与其籽粒充实度呈显著或极显著的直线正相关关系,说明提高淀粉直/支比可以提高籽粒充实度。